EPA METHODS 525/625/8270



SEMI-VOLATILE ORGANICS by GC/MS

EPA METHOD 625

1.0 SCOPE AND PURPOSE

This method is used for the determination of semi-volatile organic compounds in municipal and industrial discharges as provided in 40 CFR Part 136.1. The instrument used is a Varian Saturn Ion Trap GC/MS.

2.0 INTERFERENCES

Major positive interferences are produced by semi-volatile contaminants introduced to the sample during sample collection, and/or sample preparation. All reagents and apparatus must be free from contaminants, especially phthalates.

1. A method blank should be run with every set of samples extracted to demonstrate lack of significant contamination.

2. A solvent blank should be run with every analytical batch to demonstrate that the GC/MS system is not contributing to any contamination.

3. Used glassware should be rinsed with acetone and reagent water as soon as possible after use. Dry and heat in a muffle at 400°C for 1 hour. Store clean glassware in a clean environment, inverted and capped with aluminum foil.

4. Use high purity reagents and GC grade solvents to minimize interference problems.

5. Negative interferences are produced by very high concentrations of hydrocarbons or analytes. Dilute extracts as necessary to ensure accurate quantitation.

3.0 SAFETY

Exercise caution, wear safety glasses and gloves, and handle solvents and standards in a fume hood. Many of these compounds are suspected carcinogens. Refer to the OSHA regulations and MSDS for more information.

4.0 PRESERVATION AND STORAGE

4.1 All samples must be iced or refrigerated at 4°C from time of collection until extraction. Fill the sample bottles and, if residual chlorine is present, add 80 mg sodium thiosulfate per liter of sample and mix well.

4.2 Samples must be extracted within 7 days of collection and completely analyzed within 40 days of extraction.

5.0 EQUIPMENT

1. Varian Saturn GC/MS/DS, consisting of a Varian 3900 GC with a split/splitless injector, Varian 2100T ion trap mass spectrometer, and a Saturn GC/MS Workstation data system on a desktop PC.

2. Column: J&W DB-5ms, 30 meter x 0.25mm id, 0.25um phase thickness.

3. Corning Accelerated One-Step continuous liquid/liquid extraction apparatus.

4. Corning membranes (cat. #3918-47) for the Accelerated One-Step Extractors.

5. Glass wool – muffled at 400oC for 2 hours.

6. Labconco RapidVap automatic concentrator.

7. Millipore Elix 3 reverse osmosis and Milli-Q TOC Plus polishing unit.

6.0 REAGENTS

1. Reagent water, obtained fresh from Milli-Q system.

2. Sodium hydroxide solution (6 M NaOH) - 279 mL of JT Baker 50% NaOH solution + 621 mL reagent water.

6.3 Sodium thiosulfate, (ACS) Granular.

6.4 Sulfuric acid – EM Science 96% Suprapur H2SO4.

5. Methylene chloride - Pesticide quality or equivalent.

6. Stock standard solutions. Commercially prepared at concentrations of 2000 µg/mL or less. Sources are Supelco, Ultra Scientific and AccuStandard. Use separate sources, or at a minimum, separate lot numbers, for preparation of initial calibration standards and calibration check standards. The following standards are used to prepare solutions for a 6-level i calibration:

1. Ultra Scientific cat. #US-100N, Base/Neutral Mix #1, 2000 µg/mL.

2. Ultra Scientific cat. #US-101N, Base/Neutral Mix #2, 2000 µg/mL.

3. Ultra Scientific cat. #US-103N, Toxic Substance Mix #1, 2000 µg/mL.

4. Ultra Scientific cat. #US-104N, Toxic Substance Mix #2, 2000 µg/mL.

5. Ultra Scientific cat. #US-105N, Benzidine Mix, 2000 µg/mL.

6. Ultra Scientific cat. #US-106N, PAH Mix, 2000 µg/mL.

7. Ultra Scientific cat. #US-107N, Phenols Mix, 2000 µg/mL.

8. Ultra Scientific cat. #RCC-198, Pyridine (2000 µg/mL, made from neat).

9. AccuStandard cat. M-8270-SS, Surrogate Mix, 4000 µg/mL.

10. AccuStandard cat. #Z-014J, Internal Standard Mix, 4000 µg/mL.

Store stock standards at 4 oC or less. Keep a maximum of six months if open or up to expiration date provided by manufacturer is ampule has not been opened.

Calibration Standards Preparation

|IC Standards |Solutions #1-8 |Surrogate (#9) |I.S. (#10) |CH2Cl2 |

|120 µg/mL |60 µL each |30 µL |10 µL |490 µL |

|80 µg/mL |40 µL each |20 µL |10 µL |660 µL |

|50 µg/mL |25 µL each |12.5 µL |10 µL |790 µL |

|20 µg/mL |10 µL each |5 µL |10 µL |915 µL |

|5 µg/mL |100 µL of 50 µg/mL cal std |-- |9 µL |900 µL |

|1 µg/mL |50 µL of 20 µg/mL cal std |-- |9.5 µL |950 µL |

6.7 Surrogate standard spiking solution: Surrogate solution at 100 µg/ml in acetone. Ultra Scientific cat. # ISM-331 containing 2-fluorobiphenyl, 2-fluorophenol, nitrobenzene-d5, phenol-d5, p-terphenyl-d14, and 2,4,6-tribromophenol, all at 4000 µg/ml. Dilute 2.5 ml to 100 ml with acetone.

6.8 Internal standard spiking solution: Ultra Scientific Cat # US-108N-4, internal standard mixture at 4 mg/mL. Use 10 µL per ml of extract.

9. Tuning/tailing standard - 50 µg/ml DFTPP, 50 µg/ml Pentachlorophenol,

100 µg/ml Benzidine in methylene chloride. Stock solutions are Ultra Scientific #GCS-120 (Pentachlorophenol @ 1000 µg/ml) and #GCS-130 (DFTPP @

1000 µg/mL and benzidine @ 2000 µg/mL). Take 50 µL each from #GCS-120 and GCS-130, add this to 900 µL of methylene chloride in a 2 ml vial.

10. Spike solution @ 100 µg/mL. Ultra Scientific solutions @ 2000 µg/mL:

1. SVM-102. Base/Neutral Extractables Mix

2. US-103N-4. Toxic Substance Mix #1

3. US-104N-4. Toxic Substance Mix #2

4. US-105N-4. Benzidine Mix

5. US-107N-4. Phenol Mix

6. RCC-198. Pyridine (make from neat)

Fill a 50-mL volumetric flask half full with acetone, add 2.5-mL from each of the above six solutions, then bring to mark with acetone.

7.0 CALIBRATION AND MAINTENANCE

Demonstration and documentation of acceptable initial calibration is required before any samples are analyzed and is required intermittently throughout sample analysis as dictated by results of continuing calibration checks. A calibration check must be analyzed at the beginning of each analytical run, every 12-hour period thereafter, and at the end of each analytical run.

7.1 Calibration

7 Calibrate the mass and abundance scales of the MS with calibration compounds and procedures prescribed by the manufacturer with any modifications necessary to meet the requirements in Table A3.

7.1.2 Inject into the GC a 1µL aliquot of the 50 µg/L DFTPP/Pentachlorophenol/Benzidine Tuning/Tailing standard solution (6.10). Use the GC conditions listed in Table A2. Acquire a background corrected spectrum of DFTPP and confirm that all the key m/z criteria in Table A3 are achieved. In addition, confirm that the tailing factor for pentachlorophenol is less than 5, and the tailing factor for benzidine is less than 3. If any of these criteria are not met, the GC and/or the MS must be adjusted/serviced until all of the above criteria are met.

7.1.3 Prepare a series of 6 standards as follows: 1, 5, 20, 50, 80 and 120 µg/Ml in methylene chloride. Standards should include all compounds listed in Table A1, including surrogates. Refer to section 6.6 for the preparation of calibration standards.

4. Inject 1 µL of each of the 6 standards into the GC, low concentration to high, using GC program in Table A5. Refer to 9.2 for processing the 6-point calibration. The relative standard deviation of all of the response factors should be less than 30%. Alternatively, a linear or second order regression can be used. The coefficient of variance for the linear/second order regression should be 0.998 or greater. If these criteria cannot be met, refer to 7.2.3 for remedies.

7.2 Continuing Calibration

7.2.1 On a daily basis, inject 1 µL of a Continuing Calibration Check Std at 50 µg/Ml. The CCC standard should be prepared from stock solutions independent of those used for the 6-level calibration (i.e. different manufacturer or different lot number). If more than 10% of the CCC compounds differ from the average response of the 6- level calibration by more than ±20%, re-calibration is necessary. And, if the CCC continues to fail, a fresh CCC standard needs to be prepared. Finally, if that does not resolve the problem, any of the remedial actions listed in 7.2.3 may be taken. If remedial action is taken, a new 6-level calibration curve may be required. Once the 6-level calibration and continuing calibration requirements are met, sample analysis may begin.

7.2.2 All detected target analytes in samples bracketed by the CCC that did not meet the criteria outlined in 7.2.1 must be flagged with a “J” in the LIMS database.

7.2.3 Possible remedial actions should ICAL or CCC parameters not meet specifications:

• Check and adjust GC and/or MS operating conditions, and, if necessary, do an MS auto-tune. Check the air/water ratio, tune the electron multiplier and do a FC-43 mass calibration.

• Replace injector liner or any components that allow analytes to come in contact with hot metal surfaces.

• Clean the ion trap electrodes and spacers.

• Replace the MS electron multiplier, or any other faulty components.

3. Maintenance

7 The main purpose of the daily injections of benzidine and pentachlorophenol is to monitor the status of the injector and head of the column. After several dirty samples have been injected, the pentachlorophenol will begin to tail more, and the benzidine may disappear altogether. If either of these symptoms occur, replace the injector liner and clip about 12 inches from the head of the column. At the same time, the injector septum should be replaced. While the injector is coming back up to temperature, program the GC oven up to 330°C and hold for 5 minutes to drive off residual contaminants (i.e., finger oils) in the liner and septum. If the tailing factor continues to fail QA, repeat the above procedure and/or bake out the injector and column at 310°C for 2 hrs.

7 Depending upon the number of samples run and the “dirtiness” of the samples, the ion trap electrodes and spacers will need to be cleaned. In general, cleaning is required every 3 to 6 months. Indications of need for cleaning include inability to hold calibration, and noise and spikes when examining FC-43 spectrum.

7.3.3 Replace injector septum after approximately 100 injections.

8.0 ANALYTICAL PROCEDURE

1. Extraction

1. Samples are extracted using the Corning Accelerated One-Step liquid/liquid extractors with the re-circulating hot water bath set at 80oC. Along with each batch of samples, set up a Method Blank, Laboratory Control Spike (LCS), Spike Blank, Matrix Spike (MS), and Matrix Spike Duplicate (MSD). Inoculate the LCS with 10 µL, and the Spike Blank, MS and MSD with 1.0-mL of the matrix spiking solution (section 6.10). Add 1-mL of surrogate solution (section 6.7) to all samples. The addition of spikes and surrogates to the samples must be made below the aqueous surface.

2. Assemble the extraction apparatus. Using a Brinkman dispenser, add

50-mLs of methylene chloride into the sample vessels but not before discarding the first 10-mLs or so out of the dispenser. Keep the stopcock closed until after the addition of the sample.

3. Measure the exact volume of the sample (usually about 1 L) by marking the volume level on the sample bottle with paper correction fluid. The volume will be measured, following the setup of the extraction apparatus, by filling the sample bottle with tap water to the mark and measuring that volume in a graduated cylinder.

4. Some sample may require the addition of glass wool to the sample extractor in order to prevent clogging of the membrane. If glass wool is added to one or more sample, glass wool should also be added to the method blank, the LCS, and the spike blank. If the sample with the added glass wool was selected for spiking, glass wool should also be added to the spiked samples.

5. Prior to raising the pH, discard the first portion of base. Adjust the pH to 12 with approximately 5-mL of 6 M NaOH (section 6.2) and check the pH with a drop of sample, from a stirring rod, onto a pH test strip. Do not dip the test strip into the sample. Pour the sample into the extractor sample vessel. Rinse the sample bottle twice with 25-mL of methylene chloride and each time pouring the rinsed solvent into the sample vessel. Extract the samples for 5.5 hrs.

6. Prior to acidifying the samples for acid extraction, discard the first portion of acid from the dispenser for this may contain contaminants. Lower the pH to ................
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